def test_inverse_of_invertible_op_tree():
def rev_freeze(root):
return ops.freeze_op_tree(ops.inverse_of_invertible_op_tree(root))
operations = [
ops.Operation(_FlipGate(i), [ops.NamedQubit(str(i))])
for i in range(10)
]
expected = [
ops.Operation(_FlipGate(~i), [ops.NamedQubit(str(i))])
for i in range(10)
]
# Just an item.
assert rev_freeze(operations[0]) == expected[0]
# Flat list.
assert rev_freeze(operations) == tuple(expected[::-1])
# Tree.
assert (rev_freeze(
(operations[1:5], operations[0],
operations[5:])) == (tuple(expected[5:][::-1]), expected[0],
tuple(expected[1:5][::-1])))
# Flattening after reversing is equivalent to reversing then flattening.
t = (operations[1:5], operations[0], operations[5:])
assert (tuple(ops.flatten_op_tree(rev_freeze(t))) == tuple(
rev_freeze(ops.flatten_op_tree(t))))
def test_init():
r = ScheduledOperation(time=Timestamp(picos=5),
duration=Duration(picos=7),
operation=ops.Operation(ops.H,
[ops.NamedQubit('a')]))
assert r.time == Timestamp(picos=5)
assert r.duration == Duration(picos=7)
assert r.operation == ops.Operation(ops.H, [ops.NamedQubit('a')])
def test_validate_operation_supported_gate():
d = square_device(3, 3)
class MyGate(ops.Gate):
pass
d.validate_operation(ops.Operation(ExpZGate(), [XmonQubit(0, 0)]))
with pytest.raises(ValueError):
d.validate_operation(ops.Operation(MyGate, [XmonQubit(0, 0)]))
def test_validate_operation_adjacent_qubits():
d = square_device(3, 3)
d.validate_operation(
ops.Operation(Exp11Gate(), (XmonQubit(0, 0), XmonQubit(1, 0))))
with pytest.raises(ValueError):
d.validate_operation(
ops.Operation(Exp11Gate(), (XmonQubit(0, 0), XmonQubit(2, 0))))
def test_operation_eq():
g1 = ops.Gate()
g2 = ops.Gate()
r1 = [XmonQubit(1, 2)]
r2 = [XmonQubit(3, 4)]
r12 = r1 + r2
r21 = r2 + r1
eq = EqualsTester()
eq.make_equality_pair(lambda: ops.Operation(g1, r1))
eq.make_equality_pair(lambda: ops.Operation(g2, r1))
eq.make_equality_pair(lambda: ops.Operation(g1, r2))
eq.make_equality_pair(lambda: ops.Operation(g1, r12))
eq.make_equality_pair(lambda: ops.Operation(g1, r21))
def test_validate_operation_existing_qubits():
d = square_device(3, 3, holes=[XmonQubit(1, 1)])
d.validate_operation(
ops.Operation(Exp11Gate(), (XmonQubit(0, 0), XmonQubit(1, 0))))
d.validate_operation(ops.Operation(ExpZGate(), (XmonQubit(0, 0), )))
with pytest.raises(ValueError):
d.validate_operation(
ops.Operation(Exp11Gate(), (XmonQubit(0, 0), XmonQubit(-1, 0))))
with pytest.raises(ValueError):
d.validate_operation(ops.Operation(ExpZGate(), (XmonQubit(-1, 0), )))
with pytest.raises(ValueError):
d.validate_operation(
ops.Operation(Exp11Gate(), (XmonQubit(1, 0), XmonQubit(1, 1))))
def _wrap_operation(op: ops.Operation,
ext: extension.Extensions) -> ops.Operation:
new_qubits = [_QCircuitQubit(e) for e in op.qubits]
new_gate = ext.try_cast(op.gate, QCircuitDiagrammableGate)
if new_gate is None:
new_gate = fallback_qcircuit_extensions.cast(op.gate,
QCircuitDiagrammableGate)
return ops.Operation(_QCircuitGate(new_gate), new_qubits)
def test_operation_init():
q = XmonQubit(4, 5)
g = ops.Gate()
v = ops.Operation(g, (q,))
assert v.gate == g
assert v.qubits == (q,)
def map_operation(self, operation: ops.Operation) -> ops.Operation:
return ops.Operation(operation.gate,
[self.qubit_map(q) for q in operation.qubits])
def test_validate_measurement_non_adjacent_qubits_ok():
d = square_device(3, 3)
d.validate_operation(
ops.Operation(XmonMeasurementGate(key=''),
(XmonQubit(0, 0), XmonQubit(2, 0))))
